Detecting single gravitons with quantum sensing
ORAL
Abstract
The quantization of gravity is widely believed to result in gravitons -- particles of discrete energy that form gravitational waves. But their detection has so far been considered impossible. Here we show that signatures of single gravitons can be observed in laboratory experiments. We show that stimulated and spontaneous single-graviton processes can become relevant for massive quantum acoustic resonators and that stimulated absorption can be resolved through continuous sensing of quantum jumps. We analyze the feasibility of observing the exchange of single energy quanta between matter and gravitational waves. Our results show that single graviton signatures are within reach of experiments. In analogy to the discovery of the photo-electric effect for photons, such signatures can provide the first experimental evidence of the quantization of gravity.
*This material is based upon work supported by the National Science Foundation under Grant No. 2239498, the European Research Council under grant no. 742104, the Swedish Research Council under grant no. 2019-05615, the U.S. Department of Energy, Office of Science, ASCR under Award Number DE-SC0023291, the Branco Weiss Fellowship – Society in Science, the General Sir John Monash Foundation, and the Wallenberg Initiative on Networks and Quantum Information (WINQ). Nordita is partially supported by Nordforsk.
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Publication: G. Tobar, S. K. Manikandan, T. Beitel, I. Pikovski, Detecting single gravitons with quantum sensing, arXiv:2308.15440 (2023).
Presenters
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Germain Tobar
- Stockholm University